Mathematical Methods for Physics and Engineering : A Comprehensive Guide

(Darren Dugan) #1

11.5 SURFACE INTEGRALS


Find the vector area of the surface of the hemispherex^2 +y^2 +z^2 =a^2 ,z≥ 0 ,by
evaluating the line integralS=^12


Cr×draround its perimeter.

The perimeterCof the hemisphere is the circlex^2 +y^2 =a^2 , on which we have


r=acosφi+asinφj,dr=−asinφdφi+acosφdφj.

Therefore the cross productr×dris given by


r×dr=



∣∣




ijk
acosφasinφ 0
−asinφdφ acosφdφ 0



∣∣




=a^2 (cos^2 φ+sin^2 φ)dφk=a^2 dφk,

and the vector area becomes


S=^12 a^2 k

∫ 2 π

0

dφ=πa^2 k.

11.5.3 Physical examples of surface integrals

There are many examples of surface integrals in the physical sciences. Surface


integrals of the form (11.8) occur in computing the total electric charge on a


surface or the mass of a shell,



Sρ(r)dS, given the charge or mass densityρ(r).
For surface integrals involving vectors, the second form in (11.9) is the most


common. For a vector fielda, the surface integral



Sa·dSis called theflux
ofathroughS. Examples of physically important flux integrals are numerous.


For example, let us consider a surfaceSin a fluid with densityρ(r) that has a


velocity fieldv(r). The mass of fluid crossing an element of surface areadSin


timedtisdM=ρv·dSdt. Therefore thenettotal mass flux of fluid crossingS


isM=



Sρ(r)v(r)·dS. As a another example, the electromagnetic flux of energy
out of a given volumeVbounded by a surfaceSis



S(E×H)·dS.
The solid angle, to be defined below, subtended at a pointOby a surface (closed

or otherwise) can also be represented by an integral of this form, although it is


not strictly a flux integral (unless we imagine isotropic rays radiating fromO).


The integral


Ω=


S

r·dS
r^3

=


S

ˆr·dS
r^2

, (11.11)

gives thesolid angleΩsubtended atOby a surfaceSifris the position vector


measured fromOof an element of the surface. A little thought will show that


(11.11) takes account of all three relevant factors: the size of the element of


surface, its inclination to the line joining the element toOand the distance from


O. Such a general expression is often useful for computing solid angles when the


three-dimensional geometry is complicated. Note that (11.11) remains valid when


the surfaceSis not convex and when a single ray fromOin certain directions


would cutSin more than one place (but we exclude multiply connected regions).

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